CN109986365B

CN109986365B - Vertical steel wire mesh frame welding production line

Info

Publication number: CN109986365B
Application number: CN201910390246.7A
Authority: CN
Inventors: 厉雄伟; 王英顺; 王书元; 姜立松; 厉明阳; 战梦涵; 宋亮
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-05-10
Filing date: 2019-05-10
Publication date: 2023-05-12
Anticipated expiration: 2039-05-10
Also published as: CN109986365A

Abstract

The invention discloses a vertical steel wire mesh frame welding production line, which comprises a main frame and an auxiliary frame, wherein a channel for a steel wire mesh core plate to pass through is arranged between the main frame and the auxiliary frame, a synchronous motion mechanism capable of driving the steel wire mesh core plate to move in the channel is arranged on the auxiliary frame, one side of the main frame is rotationally connected with a rotating bracket, a straightening wire inserting cutter is arranged on the rotating bracket, a pre-jack machine capable of pre-jack operation is also arranged on the auxiliary frame for the steel wire mesh core plate in the channel, and a steel wire mesh frame welding machine capable of welding steel wires fed into a pre-jack of the steel wire mesh core plate after the straightening wire inserting cutter is cut off and the steel wire mesh on the steel wire mesh core plate is arranged on one side of the pre-jack machine; one side of the auxiliary frame is provided with a driving mechanism capable of driving the auxiliary frame to move. The invention has the following beneficial effects: the production line is applicable to the production and manufacture of the multi-specification steel wire mesh frame sandwich plate, and has the advantages of high quality and high yield.

Description

Vertical steel wire mesh frame welding production line

Technical Field

The invention relates to steel wire mesh frame production equipment, in particular to a vertical steel wire mesh frame welding production line.

Background

The steel wire mesh frame sandwich plate is used as a wall material and is widely used for the partition of non-bearing outer walls and inner walls in the building field at the end of 80 s of the last century and at the beginning of 90 s. The outer heat preservation and self-heat preservation system of the outer wall is applied in the beginning of the century. With the continuous improvement of the national building energy-saving requirement and the requirement of the integration of structure and heat preservation, the application range of the steel wire mesh frame sandwich plate (hollow mesh cage) as a building material is wider and wider. At present, the equipment produced at home and abroad is divided into two types from the forming mode, wherein one type is a horizontal production line, namely the plate is horizontally placed during forming, and the other type is a vertical production line, namely the plate is vertically formed.

The domestic steel wire net frame welding production line has the common conditions of low yield, high welding leakage rate, difficult specification adjustment, low automation degree and the like. Especially with the increase of energy saving requirements, the thickness of the core material and the density of the core material are increased, and the thickness of the core material is from 50mm in the past singly to 250mm at present. The material of the core material is added into an extruded sheet, an empty net cage and the like from a polystyrene foam board and a rock wool board. The original steel wire rack welding production line is only suitable for manufacturing the steel wire rack sandwich board with single specification, is not suitable for manufacturing the steel wire rack sandwich board with multiple specifications, and is therefore to be improved.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a vertical steel wire mesh frame welding production line which is applicable to the production and manufacture of multi-specification steel wire mesh frame sandwich plates and has the advantages of high quality and high yield.

The technical aim of the invention is realized by the following technical scheme: the utility model provides a vertical wire mesh frame welding production line, includes main frame and auxiliary frame, be equipped with the passageway that can supply the wire mesh core to pass through between main frame and the auxiliary frame, be provided with the synchronous motion mechanism that can drive the wire mesh core and move in the passageway on the auxiliary frame, one side of main frame rotates and is connected with the runing rest, be provided with the alignment wire cut-off machine on the runing rest, still be provided with the pre-jack machine that can carry out the jack operation to the wire mesh core in the passageway in advance in the auxiliary frame, one side of pre-jack machine is provided with the wire mesh frame welding machine that can send into wire mesh core wire in wire mesh core wire mesh after the alignment wire cut-off machine cuts off and carry out the welding with the wire mesh on the wire mesh core; one side of the auxiliary frame is provided with a driving mechanism which can drive the auxiliary frame to move so as to enable the steel wire mesh core plates with different specifications to move in the channel.

The invention is further provided with: the driving mechanism comprises a sliding block arranged at the bottom of the auxiliary frame and a guide rail arranged on the main frame, the auxiliary frame is in sliding fit with the guide rail on the main frame through the sliding block, and a driving piece capable of driving the auxiliary frame to move along the guide rail is further arranged on one side of the auxiliary frame.

The invention is further provided with: the driving mechanism further comprises adjusting seats respectively arranged at the tops of the auxiliary frame and the main frame, one adjusting screw rod is arranged between the two adjusting seats in a penetrating mode, and the adjusting screw rods and each adjusting seat are locked and limited through fasteners.

The invention is further provided with: the straightening wire cutting machine comprises a wire placing frame, a wire straightening mechanism and a wire cutting mechanism, wherein one side of the wire straightening mechanism and one side of the wire cutting mechanism are provided with the same mounting plate, and the mounting plate is arranged on a rotating support.

The invention is further provided with: the steel wire cutting mechanism comprises a cutting cylinder arranged on a mounting plate, the free end of the cutting cylinder is rotationally connected with a cutting connecting rod, one end of the cutting connecting rod, which is far away from the cutting cylinder, is rotationally connected with a movable sliding block, a plurality of movable cutters surrounding the steel wire are arranged in the movable sliding block, one side of the movable sliding block is provided with a fixed block fixed on the mounting plate, one side of the fixed block is provided with a plurality of fixed cutter holders, each fixed cutter holder is internally provided with a fixed cutter capable of surrounding the steel wire, and the steel wire can sequentially pass through the movable cutter, the fixed cutter and the fixed cutter holders in the movable sliding block.

The invention is further provided with: the synchronous motion mechanism comprises a motion cylinder fixedly arranged on the auxiliary frame, the free end of the motion cylinder is fixedly connected with a net pushing support, a plurality of pushing hooks for moving the steel net are arranged on one side, facing the steel net core plate, of the net pushing support, a synchronous support is connected on one side of the net pushing support, a synchronous cylinder is fixedly arranged on one side of the synchronous support, and the free end of the synchronous cylinder penetrates through the synchronous support and is fixedly connected with a blade which can be inserted into the net core plate.

The invention is further provided with: one side of the push net support is provided with a holding groove, an abutting block which can be fixedly connected with the synchronous support is arranged in the holding groove, and when one end of the abutting block abuts against the wall of the holding groove, a gap exists between the other end of the abutting block and the wall of the other holding groove.

The invention is further provided with: the gap is equal to the distance between any two adjacent vertical steel wires.

The invention is further provided with: the pre-jack machine comprises a plurality of pre-inserted steel wire fixing pipes, each pre-inserted steel wire fixing pipe is coaxially arranged with a corresponding guide pipe seat, one side of each pre-inserted steel wire fixing pipe is fixedly connected with a same pre-plug board, and one side of each pre-plug board is provided with a pre-plug cylinder capable of driving the pre-plug board to reciprocate.

The invention is further provided with: the steel wire mesh frame welding machine comprises a plurality of welding parts capable of welding steel wires in the pre-insertion holes with steel wire meshes on the steel wire mesh core plate, one side of each welding part is fixedly connected with the same welding movable plate, and one side of each welding movable plate is provided with a welding cylinder capable of driving the welding movable plate to reciprocate.

In summary, the invention has the following beneficial effects: when in actual use, the driving mechanism is used for enabling the auxiliary frame to move, so that the size of a channel between the auxiliary frame and the main frame is adjusted to be suitable for moving the steel wire mesh core plates with different specifications in the channel. Because the distance between the auxiliary frame and the main frame is adjusted, the rotation angle of the rotating bracket is adjusted, so that the straightening wire inserting cutter positioned on the rotating bracket has a proper transmission position for the steel wire mesh core plate. When the steel wire mesh core plates with different specifications move to an operation area under the action of the synchronous motion mechanism, the steel wire mesh core plates are pre-inserted under the action of the pre-insertion hole machine, so that the core materials are prevented from being brought out of scraps or fragments in the traditional wire inserting process. Because the core plate materials are all insulating materials, if the core plate materials fall on a wire mesh or welding tongs, welding leakage can be caused. The core board is subjected to pre-jack operation, so that the situation is avoided. Then under the action of the straightening wire inserting cutter, the steel wire is cut and then sent into the pre-insertion holes on the net core plate, so that the wire inserting position is more accurate, the head cutting device required by excessive wire inserting exposure is eliminated, the steel wire is saved, and the equipment cost is reduced. And finally, welding the steel wires in the pre-insertion holes and the steel wire mesh on the steel wire mesh core plate through a steel wire mesh frame welding machine.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. Like elements or portions are generally identified by like reference numerals throughout the several figures. In the drawings, elements or portions thereof are not necessarily drawn to scale.

FIG. 1 is a schematic diagram of a first embodiment of the present invention;

FIG. 2 is a schematic view of the main frame and the sub-frame in FIG. 1;

FIG. 3 is an enlarged partial schematic view of the adjustment seat and adjustment screw of FIG. 2;

FIG. 4 is an enlarged view of a portion of the mounting plate and corner fitting of FIG. 2;

FIG. 5 is a schematic view of the structure of FIG. 2 in the other direction;

FIG. 6 is an enlarged view of a portion of the slider and guide rail of FIG. 5;

FIG. 7 is a schematic view of a wire severing mechanism;

FIG. 8 is a cross-sectional view of the structure of FIG. 7;

FIG. 9 is an enlarged view of a portion of the stationary blade holder and stationary blade, and the movable slider and movable blade of FIG. 8;

fig. 10 is a schematic structural view of a steel mesh core plate and a synchronous motion mechanism;

FIG. 11 is an enlarged partial schematic view of the push hook of FIG. 10;

fig. 12 is a schematic view of the structure in the other direction of fig. 10;

FIG. 13 is a schematic view of the structure of the pre-jack machine, wire rack welder, and straightening wire cutter;

fig. 14 is a schematic view of the usage state of fig. 13.

Reference numerals: 1. a main frame; 2. an auxiliary frame; 3. a steel wire mesh core plate; 4. a synchronous motion mechanism; 5. rotating the bracket; 6. straightening a wire inserting cutting machine; 7. a pre-jack machine; 8. a wire mesh frame welding machine; 9. a slide block; 10. a guide rail; 11. an adjusting seat; 12. adjusting a screw; 13. a fixing plate; 14. a corner piece; 15. a through hole; 16. a limiting piece; 17. a wire-releasing rack; 18. a steel wire straightening mechanism; 19. a wire cutting mechanism; 20. a mounting plate; 21. cutting off the cylinder; 22. cutting off the connecting rod; 23. a movable slide block; 24. a fixed block; 25. a fixed cutter holder; 26. a catheter holder; 27. a conduit; 28. a fixed cutter; 29. a motion cylinder; 30. a net pushing bracket; 31. pushing the hook; 32. a synchronous support; 33. a synchronous cylinder; 34. a blade; 35. a groove; 36. a pushing part; 37. a receiving groove; 38. an abutment block; 39. a unidirectional guide wheel; 40. pre-inserting a steel wire fixing tube; 41. pre-plugging plates; 42. pre-plugging a cylinder; 43. a welding part; 44. welding a moving plate; 45. welding a cylinder; 46. a steel wire mesh core plate feeding frame; 47. a movable knife; 48. and inserting a silk moving plate.

Detailed Description

Embodiments of the technical scheme of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for more clearly illustrating the technical aspects of the present invention, and thus are merely examples, and are not intended to limit the scope of the present invention.

It is noted that unless otherwise indicated, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this invention pertains.

As shown in fig. 1-14, a vertical steel wire mesh frame welding production line comprises a main frame 1 and an auxiliary frame 2, wherein a channel for a steel wire mesh core plate 3 to pass through is arranged between the main frame 1 and the auxiliary frame 2, and a synchronous movement mechanism 4 capable of driving the steel wire mesh core plate 3 to move in the channel is arranged on the auxiliary frame 2. One side of the main frame 1 is rotationally connected with a rotating bracket 5, the rotating bracket 5 is provided with a straightening wire inserting cutter 6, the auxiliary frame 2 is also provided with a pre-jack machine 7 which can perform pre-jack operation on the steel wire mesh core plate 3 in the channel, and one side of the pre-jack machine 7 is provided with a steel wire net frame welding machine 8 which can weld the steel wires fed into the pre-jack of the steel wire mesh core plate 3 after the straightening wire inserting cutter 6 is cut off with the steel wire mesh on the steel wire mesh core plate 3; one side of the auxiliary frame 2 is provided with a driving mechanism which can drive the auxiliary frame 2 to move so as to enable the steel wire mesh core plates 3 with different specifications to move in the channel.

When in actual use, the driving mechanism is used for enabling the auxiliary frame 2 to move, so that the size of a channel between the auxiliary frame 2 and the main frame 1 is adjusted to be suitable for moving the steel wire mesh core plates 3 with different specifications in the channel. Since the distance between the auxiliary frame 2 and the main frame 1 is adjusted, the rotation angle of the rotating bracket 5 needs to be adjusted, so that the straightening wire inserting cutter 6 positioned on the rotating bracket 5 has a proper transmission position for the steel wire mesh core plate 3. When the steel wire mesh core plates 3 with different specifications move to an operation area under the action of the synchronous motion mechanism 4, the steel wire mesh core plates 3 are pre-inserted under the action of the pre-insertion machine 7, so that the core materials are prevented from being brought out of scraps or fragments in the traditional wire inserting process. Because the core plate materials are all insulating materials, if the core plate materials fall on a wire mesh or welding tongs, welding leakage can be caused. The core plate is subjected to pre-inserting hole operation on the same axis (wire inserting) so as to avoid the situation. Then under the action of the straightening wire inserting and cutting machine 6, the steel wire is cut and then is sent into the pre-insertion holes on the net core plate, so that the wire inserting position is more accurate, the head cutting device required by excessive wire inserting and exposing is eliminated, the steel wire is saved, and the equipment cost is reduced. Finally, the steel wires in the pre-insertion holes and the steel wire mesh on the steel wire mesh core plate 3 are welded by a steel wire mesh frame welding machine 8.

Further, as shown in fig. 5 and 6, the driving mechanism includes a slider 9 disposed at the bottom of the sub-frame 2 and a guide rail 10 disposed on the main frame 1, and the sub-frame 2 is slidably engaged with the guide rail 10 on the main frame 1 through the slider 9. One side of the sub-frame 2 is further provided with a driving member (not shown in the drawings) that drives the sub-frame 2 to move along the guide rail 10. The driving member may be a mechanical structure such as an air cylinder or an oil cylinder or manually driven, and will not be described in detail herein.

Further, as shown in fig. 2-4, the driving mechanism further includes adjusting seats 11 respectively disposed at the tops of the auxiliary frame 2 and the main frame 1, the same adjusting screw 12 is disposed between the two adjusting seats 11 in a penetrating manner, and the adjusting screw 12 and each adjusting seat 11 are locked and limited by a fastener. Under the action of the driving member, the auxiliary frame 2 is in sliding fit with the guide rail 10 on the main frame 1 through the sliding block 9. When the channel between the auxiliary frame 2 and the main frame 1 can be suitable for the steel wire mesh core plate 3 with the required specification to pass through, the adjusting screw 12 is fixedly connected with the adjusting seat 11 through the fastener, so that the position distance between the limiting auxiliary frame 2 and the main frame 1 is locked.

Furthermore, the bottoms of the auxiliary frame 2 and the main frame 1 are respectively provided with the same adjusting seats 11, and the two adjusting seats 11 positioned at the bottoms are connected through an adjusting screw 12 and are locked and limited by fasteners. The auxiliary frame 2 and the top and bottom of the main frame 1 are fixed, so that the position distance between the auxiliary frame 2 and the main frame 1 is limited, and displacement is avoided in the working process.

Further, a fixing plate 13 with an arc-shaped groove is arranged on the main frame 1, a corner piece 14 capable of being matched with the fixing plate 13 is arranged on one side of the rotating bracket 5, a through hole 15 capable of being matched with the arc-shaped groove is arranged on one side of the corner piece 14, and the through hole 15 and the arc-shaped groove are matched with the same fastening bolt (not shown in the drawing). The rotating support and the main frame are limited through the rotating fixing pins, under the action of the rotating fixing pins, the rotating support 5 can only rotate along the preset angle of the arc-shaped groove, and the rotating support 5 is fastened and limited through the fastening bolts when rotating to the required angle. A limiting piece 16 capable of fixing the position of the rotating bracket 5 is arranged between the rotating bracket 5 and the main frame 1. The position of the rotating bracket 5 is limited and fixed by the action of the limiting piece 16, so that the straightening wire cutting machine 6 positioned on the rotating bracket 5 is prevented from shifting during operation.

As shown in fig. 1, 7, 8 and 9, the straightening wire cutter 6 includes a wire paying-off frame 17, a wire straightening mechanism 18 and a wire cutting mechanism 19. The wire straightening mechanism 18 and one side of the wire cutting mechanism 19 are provided with the same mounting plate 20, and the mounting plate 20 is arranged on the rotating bracket 5. The wire straightening mechanism 18 can straighten the wire from the wire-releasing frame 17 and send the straightened wire to the wire cutting mechanism 19, which is not described in detail in the prior art.

Further, the wire straightening mechanism 18 includes a wire inserting moving plate 48 for conveying the wire to the wire cutting mechanism 19, and a cylinder for driving the wire inserting moving plate to move is provided on one side of the wire inserting moving plate 48. Under the action of the air cylinder, the wire inserting moving plate is driven to move towards the steel wire cutting mechanism 19, so that the steel wire is synchronously driven to perform wire inserting operation on the steel wire cutting mechanism 19.

The steel wire cutting mechanism 19 comprises a cutting cylinder 21 arranged on the mounting plate 20, a cutting connecting rod 22 is rotatably connected to the free end of the cutting cylinder 21, a movable slide block 23 is rotatably connected to one end of the cutting connecting rod 22 away from the cutting cylinder 21, a plurality of movable cutters 47 surrounding the steel wire are arranged in the movable slide block 23, and each movable cutter 27 is fixed on the movable slide block 23 in a welding mode. The number of the movable sliders 23 may be several, and are sequentially connected. A gap with the diameter of a steel wire is reserved between every two movable sliding blocks, and under the action of the cutting cylinder 21, one movable sliding block 23 is driven to move, so that a plurality of movable sliding blocks 23 can be synchronously driven to carry out linkage. Each movable cutter 47 has the functions of guiding and cutting off, one side of the movable slide block 23 is provided with a fixed block 24 fixed on the mounting plate 20, one side of the fixed block 24 is provided with a plurality of fixed cutter holders 25, one side of each fixed cutter holder 25 is provided with a conduit seat 26, and a conduit 27 is arranged in the conduit seat 26. The fixed knife holder 25 is internally provided with a fixed knife 28 which can encircle a steel wire, and the steel wire can sequentially pass through the movable slide block 23, the movable knife 47, the fixed knife 28, the fixed knife holder 25 and the catheter holder 26. In actual use, each fixed cutter seat 25 is fixed on the fixed block 24. By driving the cutting cylinder 21, the free end of the cutting cylinder 21 drives the movable slide block 23 and the fixed knife seat 25 to move relatively through the cutting connecting rod 22, so that the fixed knife seat 25 where the fixed knife 28 is positioned and the movable slide block 23 where the movable knife 47 is positioned misplaced to cut off the steel wire, then the next slide block cuts off the steel wire, and so on; so that the cut-off wire is retained in the stationary blade holder 25 and the catheter holder 26. The cut steel wires reserved in the catheter holder 26 are jacked into the pre-insertion holes of the net core plate to realize welding under the action of the wire inserting movable plate 48. The cutting cylinder 21 is reset to drive the movable slide block 23 to reset through the cutting connecting rod 22, and the next wire inserting and cutting is waited.

Further, the fixed blade 28 and the movable blade 47 are made of hard alloy materials, so that the deformation of the cut steel wire is small, and the cut surface is smooth and burr-free.

As shown in fig. 1, 10, 11 and 12, the synchronous movement mechanism 4 comprises a movement cylinder 29 fixedly arranged on the auxiliary frame 2, a net pushing support 30 is fixedly connected to the free end of the movement cylinder 29, and a plurality of pushing hooks 31 for moving the steel wire mesh are arranged on one side of the net pushing support 30 facing the steel wire mesh core plate 3. One side of the net pushing support 30 is connected with a synchronous support 32, one side of the synchronous support 32 is fixedly provided with a synchronous cylinder 33, and the free end of the synchronous cylinder 33 penetrates through the synchronous support 32 to be fixedly connected with a blade 34 which can be inserted into the net core plate. The shape of the blade changes according to the change of the material of the core material. When in use, the net pushing support 30 and the synchronous support 32 can be synchronously driven to move under the action of the moving air cylinder 29, the net pushing support 30 pushes the steel wire net to move through the pushing hook 31, and the synchronous support 32 inserts the blade 34 into the net core plate through the synchronous air cylinder 33 so as to drive the net core plate to synchronously move. The synchronous movement process of the net core plate and the steel wire net is realized through the operation.

Further, each push hook 31 is provided with a groove 35 which can be matched with the transverse steel wire and a pushing part 36 which is abutted against the vertical steel wire. Because the steel wire mesh is a grid-like structure formed by a plurality of transverse steel wires and a plurality of vertical steel wires, the push hooks 31 are embedded into the grooves 35 when in use, and the push hooks 31 can push the steel wire mesh transversely through the pushing parts 36 when moving transversely, so that the purpose of moving the steel wire mesh is achieved.

Further, a receiving groove 37 is provided on one side of the push net support 30, and an abutment block 38 fixedly connected to the synchronous support 32 is provided in the receiving groove 37. When one end of the abutting block 38 abuts against the groove wall of the accommodation groove 37, the other end of the abutting block 38 has a clearance with the groove wall of the other accommodation groove 37. The gap is the same size as the spacing between the push portion 36 and the adjacent vertical wire. In the actual operation process, after the push hook 31 moves by the gap, the synchronous bracket 32 can drive the abutting block 38 to abut against the groove wall of the accommodating groove, and at this time, the movement of the synchronous bracket 32 can make the abutting block 38 relatively move in the accommodating groove 37. When the push hook 31 is abutted against the steel wire, one side of the abutment block 38 is synchronously abutted against the groove wall of the accommodating groove 37. At this time, the synchronous support 32 can be driven to link by moving the net pushing support 30, so as to realize synchronous movement between the steel wire net and the net core plate. When the push wire holder 30 is retracted, its movement is reversed from that described above.

Further, the synchronous movement mechanism 4 further comprises a unidirectional guide wheel 39 which can be matched with the steel wire mesh, and the unidirectional guide wheel 39 has the effect of positioning the height of the steel wire mesh and also has the effect of preventing the steel wire mesh from backing.

Further, the net pushing support 30 is slidably connected to the synchronous support 32, such that the net pushing support 30 provides a supporting force point for the synchronous support 32.

As shown in fig. 13 and 14, the pre-jack 7 comprises a plurality of pre-inserted wire-fixing pipes 40, each pre-inserted wire-fixing pipe 40 being coaxially arranged with a corresponding catheter hub 26. One side of the pre-inserted steel wire fixing pipes 40 is fixedly connected with the same pre-inserted plate 41, and one side of the pre-inserted plate 41 is provided with a pre-inserted air cylinder 42 capable of driving the pre-inserted plate 41 to reciprocate. The wire inserting movable plate 48 performs wire inserting operation to the pre-inserting holes on the steel wire mesh core plate 3 while the pre-inserting hole machine 7 is retreated.

As shown in fig. 13 and 14, the wire mesh frame welding machine 8 includes a plurality of welding parts 43 capable of welding the wire in the pre-insertion hole and the wire mesh on the wire mesh core plate 3, one side of each welding part 43 is fixedly connected with the same welding moving plate 44, and one side of the welding moving plate 44 is provided with a welding cylinder 45 capable of driving the welding moving plate 44 to reciprocate. After the welding parts 43 cut off the straightening wire inserting cutting machine 6 and then the steel wires fed into the pre-insertion holes of the steel wire mesh core plate 3 are welded with the steel wire mesh on the steel wire mesh core plate 3, the welding cylinders 45 control the welding parts 43 to retract through the welding moving plates 44, and the next cycle is waited.

Further, a wire mesh frame welding machine 8 (not shown in the drawings) is further arranged on the main frame 1, and the wire mesh frame welding machine 8 is arranged on two sides of the wire mesh core plate 3 so as to synchronously weld the wire mesh arranged on two sides of the wire mesh core plate 3 with the steel wires in the pre-insertion holes.

Further, a steel mesh core plate feeding frame 46 is provided at one side of the channel.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention, and are intended to be included within the scope of the appended claims and description.

Claims

1. A vertical steel wire net rack welding production line is characterized in that: the wire mesh core plate straightening and inserting machine comprises a main frame (1) and an auxiliary frame (2), wherein a channel through which a wire mesh core plate (3) can pass is arranged between the main frame (1) and the auxiliary frame (2), a synchronous movement mechanism (4) capable of driving the wire mesh core plate (3) to move in the channel is arranged on the auxiliary frame (2), a rotating bracket (5) is rotationally connected to one side of the main frame (1), a straightening wire inserting cutter (6) is arranged on the rotating bracket (5), a pre-jack machine (7) capable of performing pre-jack operation on the wire mesh core plate (3) in the channel is further arranged on the auxiliary frame (2), and a wire mesh frame welding machine (8) capable of cutting off the straightening wire inserting cutter (6) and then feeding steel wires in pre-jack of the wire mesh core plate (3) into the wire mesh core plate (3) to weld the wire mesh frame; one side of the auxiliary frame (2) is provided with a driving mechanism which can drive the auxiliary frame (2) to move so as to enable the steel wire mesh core plates (3) with different specifications to move in the channel;

the straightening wire cutting machine (6) comprises a wire releasing frame (17), a wire straightening mechanism (18) and a wire cutting mechanism (19), wherein one side of the wire straightening mechanism (18) and one side of the wire cutting mechanism (19) are provided with the same mounting plate (20), and the mounting plate (20) is arranged on the rotating bracket (5); the steel wire cutting mechanism (19) comprises a cutting cylinder (21) arranged on a mounting plate (20), a cutting connecting rod (22) is rotatably connected to the free end of the cutting cylinder (21), a movable sliding block (23) is rotatably connected to one end of the cutting connecting rod (22) away from the cutting cylinder (21), a plurality of movable cutters (47) encircling a steel wire are arranged in the movable sliding block (23), a fixed block (24) fixed on the mounting plate (20) is arranged on one side of the movable sliding block (23), a plurality of fixed cutter holders (25) are arranged on one side of the fixed block (24), fixed cutters (28) encircling the steel wire are arranged in each fixed cutter holder (25), and the steel wire can sequentially penetrate through the movable cutters (47), the fixed cutters (28) and the fixed cutter holders (25) in the movable sliding block (23);

synchronous motion mechanism (4) are including setting firmly in motion cylinder (29) on subframe (2), the free end fixedly connected with of motion cylinder (29) pushes away net support (30), one side that pushes away net support (30) towards wire net core (3) is provided with a plurality of and is used for removing pushing away hook (31) of wire net, one side that pushes away net support (30) is connected with synchronous support (32), synchronous cylinder (33) have been set firmly to one side of synchronous support (32), synchronous cylinder (33)'s free end passes synchronous support (32) fixedly connected with can insert blade (34) in the net core.

2. The welding production line for the vertical steel wire mesh frame, as set forth in claim 1, is characterized in that: the driving mechanism comprises a sliding block (9) arranged at the bottom of the auxiliary frame (2) and a guide rail (10) arranged on the main frame (1), the auxiliary frame (2) is in sliding fit with the guide rail (10) on the main frame (1) through the sliding block (9), and a driving piece capable of driving the auxiliary frame (2) to move along the guide rail (10) is further arranged on one side of the auxiliary frame (2).

3. A vertical wire mesh frame welding production line according to claim 2, characterized in that: the driving mechanism further comprises adjusting seats (11) which are respectively arranged at the tops of the auxiliary frame (2) and the main frame (1), one adjusting screw (12) is arranged between the two adjusting seats (11) in a penetrating mode, and the adjusting screw (12) and each adjusting seat (11) are locked and limited through fasteners.

4. The welding production line for the vertical steel wire mesh frame, as set forth in claim 1, is characterized in that: one side of the pushing net support (30) is provided with a containing groove (37), an abutting block (38) which can be fixedly connected with the synchronous support (32) is arranged in the containing groove (37), and when one end of the abutting block (38) abuts against the groove wall of the containing groove (37), a gap exists between the other end of the abutting block (38) and the groove wall of the other containing groove (37).

5. The welding production line for the vertical steel wire mesh frame, as set forth in claim 4, is characterized in that: the gap is equal to the distance between any two adjacent vertical steel wires.

6. The welding production line for the vertical steel wire mesh frame, as set forth in claim 1, is characterized in that: the pre-jack machine (7) comprises a plurality of pre-plug steel wire fixing pipes (40), each pre-plug steel wire fixing pipe (40) is coaxially arranged with a corresponding guide pipe seat (26), one side of each pre-plug steel wire fixing pipe (40) is fixedly connected with a same pre-plug board (41), and one side of each pre-plug board (41) is provided with a pre-plug air cylinder (42) capable of driving the pre-plug board (41) to reciprocate.

7. The welding production line for the vertical steel wire mesh frame, as set forth in claim 6, is characterized in that: the wire mesh frame welding machine (8) comprises a plurality of welding parts (43) capable of welding wires in the pre-insertion holes and a wire mesh on the wire mesh core plate (3), one side of each welding part (43) is fixedly connected with one welding movable plate (44), and one side of each welding movable plate (44) is provided with a welding cylinder (45) capable of driving the welding movable plate (44) to reciprocate.